Your search keyword '"Jeffrey M. Trent"' showing total 401 results

1. Molecular-guided therapy for the treatment of patients with relapsed and refractory childhood cancers: a Beat Childhood Cancer Research Consortium trial

Author

Giselle L. Saulnier Sholler, Genevieve Bergendahl, Elizabeth C. Lewis, Jacqueline Kraveka, William Ferguson, Abhinav B. Nagulapally, Karl Dykema, Valerie I. Brown, Michael S. Isakoff, Joseph Junewick, Deanna Mitchell, Jawhar Rawwas, William Roberts, Don Eslin, Javier Oesterheld, Randal K. Wada, Devang Pastakia, Virginia Harrod, Kevin Ginn, Raya Saab, Kevin Bielamowicz, Jason Glover, Eugenia Chang, Gina K. Hanna, Daniel Enriquez, Tyler Izatt, Rebecca F. Halperin, Abigail Moore, Sara A. Byron, William P. D. Hendricks, and Jeffrey M. Trent

Subjects

Neuroblastoma, CNS tumors, Rare tumors, Orphan diseases, Molecular-guided therapy, Pediatric oncology, Medicine, Genetics, QH426-470

Abstract

Abstract Background Children with relapsed central nervous system (CNS tumors), neuroblastoma, sarcomas, and other rare solid tumors face poor outcomes. This prospective clinical trial examined the feasibility of combining genomic and transcriptomic profiling of tumor samples with a molecular tumor board (MTB) approach to make real‑time treatment decisions for children with relapsed/refractory solid tumors. Methods Subjects were divided into three strata: stratum 1—relapsed/refractory neuroblastoma; stratum 2—relapsed/refractory CNS tumors; and stratum 3—relapsed/refractory rare solid tumors. Tumor samples were sent for tumor/normal whole-exome (WES) and tumor whole-transcriptome (WTS) sequencing, and the genomic data were used in a multi-institutional MTB to make real‑time treatment decisions. The MTB recommended plan allowed for a combination of up to 4 agents. Feasibility was measured by time to completion of genomic sequencing, MTB review and initiation of treatment. Response was assessed after every two cycles using Response Evaluation Criteria in Solid Tumors (RECIST). Patient clinical benefit was calculated by the sum of the CR, PR, SD, and NED subjects divided by the sum of complete response (CR), partial response (PR), stable disease (SD), no evidence of disease (NED), and progressive disease (PD) subjects. Grade 3 and higher related and unexpected adverse events (AEs) were tabulated for safety evaluation. Results A total of 186 eligible patients were enrolled with 144 evaluable for safety and 124 evaluable for response. The average number of days from biopsy to initiation of the MTB-recommended combination therapy was 38 days. Patient benefit was exhibited in 65% of all subjects, 67% of neuroblastoma subjects, 73% of CNS tumor subjects, and 60% of rare tumor subjects. There was little associated toxicity above that expected for the MGT drugs used during this trial, suggestive of the safety of utilizing this method of selecting combination targeted therapy. Conclusions This trial demonstrated the feasibility, safety, and efficacy of a comprehensive sequencing model to guide personalized therapy for patients with any relapsed/refractory solid malignancy. Personalized therapy was well tolerated, and the clinical benefit rate of 65% in these heavily pretreated populations suggests that this treatment strategy could be an effective option for relapsed and refractory pediatric cancers. Trial registration ClinicalTrials.gov, NCT02162732. Prospectively registered on June 11, 2014.

Published

2024

2. Feasibility of circulating tumor DNA analysis in dogs with naturally occurring malignant and benign splenic lesions

Author

Patricia Filippsen Favaro, Samuel D. Stewart, Bradon R. McDonald, Jacob Cawley, Tania Contente-Cuomo, Shukmei Wong, William P. D. Hendricks, Jeffrey M. Trent, Chand Khanna, and Muhammed Murtaza

Subjects

Medicine, Science

Abstract

Abstract Comparative studies of naturally occurring canine cancers have provided new insight into many areas of cancer research. Development and validation of circulating tumor DNA (ctDNA) analysis in pet dogs can help address diagnostic needs in veterinary as well as human oncology. Dogs have high incidence of naturally occurring spontaneous cancers, demonstrate molecular heterogeneity and clonal evolution during therapy, allow serial sampling of blood from the same individuals during the course of disease progression, and have relatively compressed intervals for disease progression amenable to longitudinal studies. Here, we present a feasibility study of ctDNA analysis performed in 48 dogs including healthy dogs and dogs with either benign splenic lesions or malignant splenic tumors (hemangiosarcoma) using shallow whole genome sequencing (sWGS) of cell-free DNA. To enable detection and quantification of ctDNA using sWGS, we adapted two informatic approaches and compared their performance for the canine genome. At the time of initial clinical presentation, mean ctDNA fraction in dogs with malignant splenic tumors was 11.2%, significantly higher than dogs with benign lesions (3.2%; p = 0.001). ctDNA fraction was 14.3% and 9.0% in dogs with metastatic and localized disease, respectively (p = 0.227). In dogs treated with surgical resection of malignant tumors, mean ctDNA fraction decreased from 11.0% prior to resection to 7.9% post-resection (p = 0.047 for comparison of paired samples). Our results demonstrate that ctDNA analysis is feasible in dogs with hemangiosarcoma using a cost-effective approach such as sWGS. Additional studies are needed to validate these findings, and determine the role of ctDNA to assess burden of disease and treatment response in dogs with cancer.

Published

2022

3. A pilot study of genomic‐guided induction therapy followed by immunotherapy with difluoromethylornithine maintenance for high‐risk neuroblastoma

Author

Jacqueline M. Kraveka, Elizabeth C. Lewis, Genevieve Bergendahl, William Ferguson, Javier Oesterheld, Elizabeth Kim, Abhinav B. Nagulapally, Karl J. Dykema, Valerie I. Brown, William D. Roberts, Deanna Mitchell, Don Eslin, Derek Hanson, Michael S. Isakoff, Randal K. Wada, Virginia L. Harrod, Jawhar Rawwas, Gina Hanna, William P. D. Hendricks, Sara A. Byron, Matija Snuderl, Jonathan Serrano, Jeffrey M. Trent, and Giselle L. Saulnier Sholler

Subjects

DFMO, immunotherapy, maintenance, neuroblastoma, precision medicine, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Background Survival for patients with high‐risk neuroblastoma (HRNB) remains poor despite aggressive multimodal therapies. Aims To study the feasibility and safety of incorporating a genomic‐based targeted agent to induction therapy for HRNB as well as the feasibility and safety of adding difluoromethylornithine (DFMO) to anti‐GD2 immunotherapy. Methods Twenty newly diagnosed HRNB patients were treated on this multicenter pilot trial. Molecular tumor boards selected one of six targeted agents based on tumor‐normal whole exome sequencing and tumor RNA‐sequencing results. Treatment followed standard upfront HRNB chemotherapy with the addition of the selected targeted agent to cycles 3–6 of induction. Following consolidation, DFMO (750 mg/m2 twice daily) was added to maintenance with dinutuximab and isotretinoin, followed by continuation of DFMO alone for 2 years. DNA methylation analysis was performed retrospectively and compared to RNA expression. Results Of the 20 subjects enrolled, 19 started targeted therapy during cycle 3 and 1 started during cycle 5. Eighty‐five percent of subjects met feasibility criteria (receiving 75% of targeted agent doses). Addition of targeted agents did not result in toxicities requiring dose reduction of chemotherapy or permanent discontinuation of targeted agent. Following standard consolidation, 15 subjects continued onto immunotherapy with DFMO. This combination was well‐tolerated and resulted in no unexpected adverse events related to DFMO. Conclusion This study demonstrates the safety and feasibility of adding targeted agents to standard induction therapy and adding DFMO to immunotherapy for HRNB. This treatment regimen has been expanded to a Phase II trial to evaluate efficacy.

Published

2022

4. Improved methods for RNAseq-based alternative splicing analysis

Author

Rebecca F. Halperin, Apurva Hegde, Jessica D. Lang, Elizabeth A. Raupach, C4RCD Research Group, Christophe Legendre, Winnie S. Liang, Patricia M. LoRusso, Aleksandar Sekulic, Jeffrey A. Sosman, Jeffrey M. Trent, Sampathkumar Rangasamy, Patrick Pirrotte, and Nicholas J. Schork

Subjects

Medicine, Science

Abstract

Abstract The robust detection of disease-associated splice events from RNAseq data is challenging due to the potential confounding effect of gene expression levels and the often limited number of patients with relevant RNAseq data. Here we present a novel statistical approach to splicing outlier detection and differential splicing analysis. Our approach tests for differences in the percentages of sequence reads representing local splice events. We describe a software package called Bisbee which can predict the protein-level effect of splice alterations, a key feature lacking in many other splicing analysis resources. We leverage Bisbee’s prediction of protein level effects as a benchmark of its capabilities using matched sets of RNAseq and mass spectrometry data from normal tissues. Bisbee exhibits improved sensitivity and specificity over existing approaches and can be used to identify tissue-specific splice variants whose protein-level expression can be confirmed by mass spectrometry. We also applied Bisbee to assess evidence for a pathogenic splicing variant contributing to a rare disease and to identify tumor-specific splice isoforms associated with an oncogenic mutation. Bisbee was able to rediscover previously validated results in both of these cases and also identify common tumor-associated splice isoforms replicated in two independent melanoma datasets.

Published

2021

5. Evaluation of pre-analytical factors affecting plasma DNA analysis

Author

Havell Markus, Tania Contente-Cuomo, Maria Farooq, Winnie S. Liang, Mitesh J. Borad, Shivan Sivakumar, Simon Gollins, Nhan L. Tran, Harshil D. Dhruv, Michael E. Berens, Alan Bryce, Aleksandar Sekulic, Antoni Ribas, Jeffrey M. Trent, Patricia M. LoRusso, and Muhammed Murtaza

Subjects

Medicine, Science

Abstract

Abstract Pre-analytical factors can significantly affect circulating cell-free DNA (cfDNA) analysis. However, there are few robust methods to rapidly assess sample quality and the impact of pre-analytical processing. To address this gap and to evaluate effects of DNA extraction methods and blood collection tubes on cfDNA yield and fragment size, we developed a multiplexed droplet digital PCR (ddPCR) assay with 5 short and 4 long amplicons targeting single copy genomic loci. Using this assay, we compared 7 cfDNA extraction kits and found cfDNA yield and fragment size vary significantly. We also compared 3 blood collection protocols using plasma samples from 23 healthy volunteers (EDTA tubes processed within 1 hour and Cell-free DNA Blood Collection Tubes processed within 24 and 72 hours) and found no significant differences in cfDNA yield, fragment size and background noise between these protocols. In 219 clinical samples, cfDNA fragments were shorter in plasma samples processed immediately after venipuncture compared to archived samples, suggesting contribution of background DNA by lysed peripheral blood cells. In summary, we have described a multiplexed ddPCR assay to assess quality of cfDNA samples prior to downstream molecular analyses and we have evaluated potential sources of pre-analytical variation in cfDNA studies.

Published

2018

6. Assessing Combinational Drug Efficacy in Cancer Cells by Using Image-based Dynamic Response Analysis

Author

Chao Sima, Jianping Hua, Milana Cypert, Tasha Miller, Heather M. Wilson-Robles, Jeffrey M. Trent, Edward R. Dougherty, and Michael L. Bittner

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Published

2016

7. Network Rewiring in Cancer: Applications to Melanoma Cell Lines and the Cancer Genome Atlas Patients

Author

Kuan-Fu Ding, Darren Finlay, Hongwei Yin, William P. D. Hendricks, Chris Sereduk, Jeffrey Kiefer, Aleksandar Sekulic, Patricia M. LoRusso, Kristiina Vuori, Jeffrey M. Trent, and Nicholas J. Schork

Subjects

network rewiring, melanoma, pathway analysis, bioinformatics and computational biology, machine learning, drug interactions, Genetics, QH426-470

Abstract

Genes do not work in isolation, but rather as part of networks that have many feedback and redundancy mechanisms. Studying the properties of genetic networks and how individual genes contribute to overall network functions can provide insight into genetically-mediated disease processes. Most analytical techniques assume a network topology based on normal state networks. However, gene perturbations often lead to the rewiring of relevant networks and impact relationships among other genes. We apply a suite of analysis methodologies to assess the degree of transcriptional network rewiring observed in different sets of melanoma cell lines using whole genome gene expression microarray profiles. We assess evidence for network rewiring in melanoma patient tumor samples using RNA-sequence data available from The Cancer Genome Atlas. We make a distinction between “unsupervised” and “supervised” network-based methods and contrast their use in identifying consistent differences in networks between subsets of cell lines and tumor samples. We find that different genes play more central roles within subsets of genes within a broader network and hence are likely to be better drug targets in a disease state. Ultimately, we argue that our results have important implications for understanding the molecular pathology of melanoma as well as the choice of treatments to combat that pathology.

Published

2018

8. Molecular Guided Therapy Provides Sustained Clinical Response in Refractory Choroid Plexus Carcinoma

Author

Albert Cornelius, Jessica Foley, Jeffrey Bond, Abhinav B. Nagulapally, Julie Steinbrecher, William P. D. Hendricks, Maria Rich, Sangeeta Yendrembam, Genevieve Bergendahl, Jeffrey M. Trent, and Giselle S. Sholler

Subjects

choroid plexus carcinoma, molecular guided therapy, mTOR, TP53, IDH2, Therapeutics. Pharmacology, RM1-950

Abstract

Choroid plexus carcinomas (CPCs) are rare, aggressive pediatric brain tumors with no established curative therapy for relapsed disease, and poor survival rates. TP53 Mutation or dysfunction correlates with poor or no survival outcome in CPCs. Here, we report the case of a 4 month-old female who presented with disseminated CPC. After initial response to tumor resection and adjuvant-chemotherapy, the tumor recurred and metastasized with no response to aggressive relapse therapy suggesting genetic predisposition. This patient was then enrolled to a Molecular Guided Therapy Clinical Trial. Genomic profiling of patient tumor and normal sample identified a TP53 germline mutation with loss of heterozygosity, somatic mutations including IDH2, and aberrant activation of biological pathways. The mutations were not targetable for therapy. However, targeting the altered biological pathways (mTOR, PDGFRB, FGF2, HDAC) guided identification of possibly beneficial treatment with a combination of sirolimus, thalidomide, sunitinib, and vorinostat. This therapy led to 92% reduction in tumor size with no serious adverse events, excellent quality of life and long term survival.

Published

2017

9. Assessing Combinational Drug Efficacy in Cancer Cells by Using Image-based Dynamic Response Analysis

Author

Chao Sima, Jianping Hua, Milana Cypert, Tasha Miller, Heather M. Wilson-Robles, Jeffrey M. Trent, Edward R. Dougherty, and Michael L. Bittner

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

The landscape of translational research has been shifting toward drug combination therapies. Pairing of drugs allows for more types of drug interaction with cells. In order to accurately and comprehensively assess combinational drug efficacy, analytical methods capable of recognizing these alternative reactions will be required to prioritize those drug candidates having better chances of delivering appreciable therapeutic benefits. Traditional efficacy measures are primarily based on the “extent” of drug inhibition, which is the percentage of cells being killed after drug exposure. Here, we introduce a second dimension of evaluation criterion, speed of killing, based on a live cell imaging assay. This dynamic response trajectory approach takes advantage of both “extent” and “speed” information and uncovers synergisms that would otherwise be missed, while also generating hypotheses regarding important mechanistic modes of drug action.

Published

2015

10. Supplementary Tables S1-S9 from Histone Deacetylase Inhibitors Synergize with Catalytic Inhibitors of EZH2 to Exhibit Antitumor Activity in Small Cell Carcinoma of the Ovary, Hypercalcemic Type

Author

David G. Huntsman, Bernard E. Weissman, Jeffrey M. Trent, Gregg B. Morin, T. Michael Underhill, Ralf Hass, Anthony N. Karnezis, Marcel B. Bally, William P.D. Hendricks, Jessica D. Lang, Krystal A. Orlando, Nancy Dos Santos, Chae Young Shin, Galen Lambert, Shane Colborne, Shary Yuting Chen, and Yemin Wang

Abstract

Table S1 shows the cell viability inhibitory rate (%) in SCCOHT cell lines vs other cell lines in the epigenetic drug screen. Table S2 shows the effects of Quisinostat on the proteome of BIN67 cells after treatment for 24 or 72 hours. Table S3 shows the significantly altered proteins by Quisinostat treatment for 24 hours in BIN67 cells. Table S4 shows the significantly altered proteins by Quisinostat treatment for 72 hours in BIN67 cells. Table S5 shows the biological functions that were significantly affected by Quisinostat treatment for 72 hours in BIN67 cells. Table S6 shows the proteins that were significantly regulated by SMARCA4 re-expression in BIN67 cells. Table S7 shows the biological functions that were significantly affected by SMARCA4 re-expression in BIN67 cells. Table S8 shows the proteins that were significantly regulated by both Quisinostat treatment (72 hr) and SMARCA4 re-expression in BIN67 cells. Table S9 shows the biological functions that were significantly affected by both Quisinostat and SMARCA4 re-expression in BIN67 cells.

Published

2023

11. Supplementary Tables 1-3, Figures 1-4 from High-throughput RNAi Screening Identifies a Role for TNK1 in Growth and Survival of Pancreatic Cancer Cells

Author

David O. Azorsa, Spyro Mousses, Daniel D. Von Hoff, Jeffrey M. Trent, Ashish Choudhary, Shilpi Arora, Irma M. Gonzales, and Meredith C. Henderson

Abstract

Supplementary Tables 1-3, Figures 1-4 from High-throughput RNAi Screening Identifies a Role for TNK1 in Growth and Survival of Pancreatic Cancer Cells

Published

2023

12. Supplementary Table 6 from Genome and Transcriptome Sequencing in Prospective Metastatic Triple-Negative Breast Cancer Uncovers Therapeutic Vulnerabilities

Author

John D. Carpten, Daniel Von Hoff, Spyro Mousses, Jeffrey M. Trent, Anthony W. Tolcher, Bodour Salhia, Paul R. Billings, Linh Hoang, Asim Siddiqui, Francisco M. De La Vega, Onur Sakarya, Catalin Barbacioru, Julie Koeman, Angela Baker, Ahmet Kurdoglu, Tyler Izatt, Cynthia R. Osborne, Cristi L. Aitelli, Joanne L. Blum, Alexis Christoforides, Jennifer Dinh, Shukmei Wong, Tracy M. Moses, Shripad Sinari, Jessica Aldrich, Jeffrey A. Kiefer, Joyce A. O'Shaughnessy, and David W. Craig

Abstract

XLSX file - 23K, Mapping statistics for genome sequencing of tumor and germline DNA from mTNBC

Published

2023

13. Banner Authorship Members from Priorities to Promote Participant Engagement in the Participant Engagement and Cancer Genome Sequencing (PE-CGS) Network

Author

John FP. Bridges, Cheryl Willman, Nikhil Wagle, Roel GW. Verhaak, Jeffrey M. Trent, Jessica C. Tiner, Andrew L. Sussman, Mariana C. Stern, Charité Ricker, Timothy R. Rebbeck, Electra D. Paskett, Shiraz I. Mishra, Qin Ma, Heinz-Josef Lenz, Bethany M. Kwan, Katherine A. Janeway, Ryan C. Fields, Bettina F. Drake, Li Ding, Graham A. Colditz, Elizabeth B. Claus, John D. Carpten, Cindy K. Blair, Melinda Bachini, Norah L. Crossnohere, and Anne LR. Schuster

Abstract

Banner authorship list

Published

2023

14. Supplementary Table 9 from Genome and Transcriptome Sequencing in Prospective Metastatic Triple-Negative Breast Cancer Uncovers Therapeutic Vulnerabilities

Author

John D. Carpten, Daniel Von Hoff, Spyro Mousses, Jeffrey M. Trent, Anthony W. Tolcher, Bodour Salhia, Paul R. Billings, Linh Hoang, Asim Siddiqui, Francisco M. De La Vega, Onur Sakarya, Catalin Barbacioru, Julie Koeman, Angela Baker, Ahmet Kurdoglu, Tyler Izatt, Cynthia R. Osborne, Cristi L. Aitelli, Joanne L. Blum, Alexis Christoforides, Jennifer Dinh, Shukmei Wong, Tracy M. Moses, Shripad Sinari, Jessica Aldrich, Jeffrey A. Kiefer, Joyce A. O'Shaughnessy, and David W. Craig

Abstract

XLSX file - 45K, Genes containing breakpoint from translocation in mTNBC

Published

2023

15. Supplemental Figures S1-S10 from Histone Deacetylase Inhibitors Synergize with Catalytic Inhibitors of EZH2 to Exhibit Antitumor Activity in Small Cell Carcinoma of the Ovary, Hypercalcemic Type

Author

David G. Huntsman, Bernard E. Weissman, Jeffrey M. Trent, Gregg B. Morin, T. Michael Underhill, Ralf Hass, Anthony N. Karnezis, Marcel B. Bally, William P.D. Hendricks, Jessica D. Lang, Krystal A. Orlando, Nancy Dos Santos, Chae Young Shin, Galen Lambert, Shane Colborne, Shary Yuting Chen, and Yemin Wang

Abstract

Fig.S1 shows that SCCOHT cells are sensitive to HDAC inhibition. Fig. S2 shows that SCCOHT cells are sensitive to HDAC inhibition or depletion. Fig.S3 shows that SMARCA4/A2 dual deficiency is not associated with hypersensitivity to HDAC inhibitors in lung and pancreatic cancer cell lines. Fig.S4 shows that pan-HDAC inhibitors induce cell morphology changes in SCCOHT cells. Fig.S5 shows that SMARCA2 activation is partially required for the hypersensitivity of SCCOHT cells to HDAC inhibition. Fig. S6 shows the effect of quisinostat on mouse body weights in BIN67 mouse xenograft models. Fig.S7 shows the synergistic effects between HDAC inhibitors and EZH2 inhibitors in SWI/SNF deficiency-driven tumor cells. Fig. S8 shows that depletion of HDAC2 increased sensitivity of BIN67 cells to EPZ-6438 treatment. Fig.S9 shows the synergistic effects between HDAC inhibitors and EZH2 inhibitors in SCCOHT cells. Fig.S10 shows the effect of combined treatment of EPZ-6438 and quisinostat on mouse body weight and survival.

Published

2023

16. Data from Histone Deacetylase Inhibitors Synergize with Catalytic Inhibitors of EZH2 to Exhibit Antitumor Activity in Small Cell Carcinoma of the Ovary, Hypercalcemic Type

Author

David G. Huntsman, Bernard E. Weissman, Jeffrey M. Trent, Gregg B. Morin, T. Michael Underhill, Ralf Hass, Anthony N. Karnezis, Marcel B. Bally, William P.D. Hendricks, Jessica D. Lang, Krystal A. Orlando, Nancy Dos Santos, Chae Young Shin, Galen Lambert, Shane Colborne, Shary Yuting Chen, and Yemin Wang

Abstract

Small cell carcinoma of the ovary, hypercalcemic type (SCCOHT) is a rare but extremely lethal malignancy that mainly impacts young women. SCCOHT is characterized by a diploid genome with loss of SMARCA4 and lack of SMARCA2 expression, two mutually exclusive ATPases of the SWI/SNF chromatin-remodeling complex. We and others have identified the histone methyltransferase EZH2 as a promising therapeutic target for SCCOHT, suggesting that SCCOHT cells depend on the alternation of epigenetic pathways for survival. In this study, we found that SCCOHT cells were more sensitive to pan-HDAC inhibitors compared with other ovarian cancer lines or immortalized cell lines tested. Pan-HDAC inhibitors, such as quisinostat, reversed the expression of a group of proteins that were deregulated in SCCOHT cells due to SMARCA4 loss, leading to growth arrest, apoptosis, and differentiation in vitro and suppressed tumor growth of xenografted tumors of SCCOHT cells. Moreover, combined treatment of HDAC inhibitors and EZH2 inhibitors at sublethal doses synergistically induced histone H3K27 acetylation and target gene expression, leading to rapid induction of apoptosis and growth suppression of SCCOHT cells and xenografted tumors. Therefore, our preclinical study highlighted the therapeutic potential of combined treatment of HDAC inhibitors with EZH2 catalytic inhibitors to treat SCCOHT.

Published

2023

17. Supplementary Figure S1 from Loss of Inositol Polyphosphate 5-Phosphatase Is an Early Event in Development of Cutaneous Squamous Cell Carcinoma

Author

Michael Bittner, Jeffrey M. Trent, Brian J. Nickoloff, David DiCaudo, Mark R. Pittelkow, David S. Alberts, James Warneke, G. Timothy Bowden, Robert Krouse, Clara Curiel-Lewandrowski, Paul Sagerman, Anil Prasad, Janine G. Einspahr, Stephanie Savage, Galen Hostetter, Su Y. Kim, and Aleksandar Sekulic

Abstract

Supplementary Figure S1 from Loss of Inositol Polyphosphate 5-Phosphatase Is an Early Event in Development of Cutaneous Squamous Cell Carcinoma

Published

2023

18. Supplementary Table 8 from Genome and Transcriptome Sequencing in Prospective Metastatic Triple-Negative Breast Cancer Uncovers Therapeutic Vulnerabilities

Author

John D. Carpten, Daniel Von Hoff, Spyro Mousses, Jeffrey M. Trent, Anthony W. Tolcher, Bodour Salhia, Paul R. Billings, Linh Hoang, Asim Siddiqui, Francisco M. De La Vega, Onur Sakarya, Catalin Barbacioru, Julie Koeman, Angela Baker, Ahmet Kurdoglu, Tyler Izatt, Cynthia R. Osborne, Cristi L. Aitelli, Joanne L. Blum, Alexis Christoforides, Jennifer Dinh, Shukmei Wong, Tracy M. Moses, Shripad Sinari, Jessica Aldrich, Jeffrey A. Kiefer, Joyce A. O'Shaughnessy, and David W. Craig

Abstract

XLSX file - 273K, Somatic genic focal copy number changes in mTNBC

Published

2023

19. Supplementary Table 3 from Genome and Transcriptome Sequencing in Prospective Metastatic Triple-Negative Breast Cancer Uncovers Therapeutic Vulnerabilities

Author

John D. Carpten, Daniel Von Hoff, Spyro Mousses, Jeffrey M. Trent, Anthony W. Tolcher, Bodour Salhia, Paul R. Billings, Linh Hoang, Asim Siddiqui, Francisco M. De La Vega, Onur Sakarya, Catalin Barbacioru, Julie Koeman, Angela Baker, Ahmet Kurdoglu, Tyler Izatt, Cynthia R. Osborne, Cristi L. Aitelli, Joanne L. Blum, Alexis Christoforides, Jennifer Dinh, Shukmei Wong, Tracy M. Moses, Shripad Sinari, Jessica Aldrich, Jeffrey A. Kiefer, Joyce A. O'Shaughnessy, and David W. Craig

Abstract

XLSX file - 598K, edgeR differential expression results in mTNBC for select cancer related genes

Published

2023

20. Data from Loss of Inositol Polyphosphate 5-Phosphatase Is an Early Event in Development of Cutaneous Squamous Cell Carcinoma

Author

Michael Bittner, Jeffrey M. Trent, Brian J. Nickoloff, David DiCaudo, Mark R. Pittelkow, David S. Alberts, James Warneke, G. Timothy Bowden, Robert Krouse, Clara Curiel-Lewandrowski, Paul Sagerman, Anil Prasad, Janine G. Einspahr, Stephanie Savage, Galen Hostetter, Su Y. Kim, and Aleksandar Sekulic

Abstract

Cutaneous squamous cell carcinoma (SCC) occurs commonly and can metastasize. Identification of specific molecular aberrations and mechanisms underlying the development and progression of cutaneous SCC may lead to better prognostic and therapeutic approaches and more effective chemoprevention strategies. To identify genetic changes associated with early stages of cutaneous SCC development, we analyzed a series of 40 archived skin tissues ranging from normal skin to invasive SCC. Using high-resolution array-based comparative genomic hybridization, we identified deletions of a region on chromosome 10q harboring the INPP5A gene in 24% of examined SCC tumors. Subsequent validation by immunohistochemistry on an independent sample set of 71 SCC tissues showed reduced INPP5A protein levels in 72% of primary SCC tumors. Decrease in INPP5A protein levels seems to be an early event in SCC development, as it also is observed in 9 of 26 (35%) examined actinic keratoses, the earliest stage in SCC development. Importantly, further reduction of INPP5A levels is seen in a subset of SCC patients as the tumor progresses from primary to metastatic stage. The observed frequency and pattern of loss indicate that INPP5A, a negative regulator of inositol signaling, may play a role in development and progression of cutaneous SCC tumors. Cancer Prev Res; 3(10); 1277–83. ©2010 AACR.

Published

2023

21. Supplementary Table 5 from Genome and Transcriptome Sequencing in Prospective Metastatic Triple-Negative Breast Cancer Uncovers Therapeutic Vulnerabilities

Author

John D. Carpten, Daniel Von Hoff, Spyro Mousses, Jeffrey M. Trent, Anthony W. Tolcher, Bodour Salhia, Paul R. Billings, Linh Hoang, Asim Siddiqui, Francisco M. De La Vega, Onur Sakarya, Catalin Barbacioru, Julie Koeman, Angela Baker, Ahmet Kurdoglu, Tyler Izatt, Cynthia R. Osborne, Cristi L. Aitelli, Joanne L. Blum, Alexis Christoforides, Jennifer Dinh, Shukmei Wong, Tracy M. Moses, Shripad Sinari, Jessica Aldrich, Jeffrey A. Kiefer, Joyce A. O'Shaughnessy, and David W. Craig

Abstract

XLSX file - 607K, Outlier differential expression results in mTNBC for select cancer related genes

Published

2023

22. Supplementary Table 7 from Genome and Transcriptome Sequencing in Prospective Metastatic Triple-Negative Breast Cancer Uncovers Therapeutic Vulnerabilities

Author

John D. Carpten, Daniel Von Hoff, Spyro Mousses, Jeffrey M. Trent, Anthony W. Tolcher, Bodour Salhia, Paul R. Billings, Linh Hoang, Asim Siddiqui, Francisco M. De La Vega, Onur Sakarya, Catalin Barbacioru, Julie Koeman, Angela Baker, Ahmet Kurdoglu, Tyler Izatt, Cynthia R. Osborne, Cristi L. Aitelli, Joanne L. Blum, Alexis Christoforides, Jennifer Dinh, Shukmei Wong, Tracy M. Moses, Shripad Sinari, Jessica Aldrich, Jeffrey A. Kiefer, Joyce A. O'Shaughnessy, and David W. Craig

Abstract

XLSX file - 61K, List of somatic point mutations in mTNBC detected by NGS sequencing analysis

Published

2023

23. Supplementary Table 4 from Genome and Transcriptome Sequencing in Prospective Metastatic Triple-Negative Breast Cancer Uncovers Therapeutic Vulnerabilities

Author

John D. Carpten, Daniel Von Hoff, Spyro Mousses, Jeffrey M. Trent, Anthony W. Tolcher, Bodour Salhia, Paul R. Billings, Linh Hoang, Asim Siddiqui, Francisco M. De La Vega, Onur Sakarya, Catalin Barbacioru, Julie Koeman, Angela Baker, Ahmet Kurdoglu, Tyler Izatt, Cynthia R. Osborne, Cristi L. Aitelli, Joanne L. Blum, Alexis Christoforides, Jennifer Dinh, Shukmei Wong, Tracy M. Moses, Shripad Sinari, Jessica Aldrich, Jeffrey A. Kiefer, Joyce A. O'Shaughnessy, and David W. Craig

Abstract

XLSX file - 42K, Ingenuity Canonical Pathways results for mTNBC based on edgeR differential expression results

Published

2023

24. Supplementary Table 1 from Genome and Transcriptome Sequencing in Prospective Metastatic Triple-Negative Breast Cancer Uncovers Therapeutic Vulnerabilities

Author

John D. Carpten, Daniel Von Hoff, Spyro Mousses, Jeffrey M. Trent, Anthony W. Tolcher, Bodour Salhia, Paul R. Billings, Linh Hoang, Asim Siddiqui, Francisco M. De La Vega, Onur Sakarya, Catalin Barbacioru, Julie Koeman, Angela Baker, Ahmet Kurdoglu, Tyler Izatt, Cynthia R. Osborne, Cristi L. Aitelli, Joanne L. Blum, Alexis Christoforides, Jennifer Dinh, Shukmei Wong, Tracy M. Moses, Shripad Sinari, Jessica Aldrich, Jeffrey A. Kiefer, Joyce A. O'Shaughnessy, and David W. Craig

Abstract

XLSX file - 40K, Characteristics of mTNBC study population

Published

2023

25. Supplementary Data from Loss-of-Function Fibroblast Growth Factor Receptor-2 Mutations in Melanoma

Author

Pamela M. Pollock, Moosa Mohammadi, Paul S. Meltzer, Boris C. Bastian, Jeffrey M. Trent, Graham J. Mann, Erica Riedesel, Ursula L. Harper, Pilar Hyder, John A. Curtin, Jinghong Ma, Anna V. Eliseenkova, Laura M. Yudt, Ana Bengston, Candice L. Wellens, Amy V. Curtis, Sara A. Byron, Omar A. Ibrahimi, Huaibin Chen, and Michael G. Gartside

Abstract

Supplementary Data from Loss-of-Function Fibroblast Growth Factor Receptor-2 Mutations in Melanoma

Published

2023

26. Supplementary Figure 3 from Genome and Transcriptome Sequencing in Prospective Metastatic Triple-Negative Breast Cancer Uncovers Therapeutic Vulnerabilities

Author

John D. Carpten, Daniel Von Hoff, Spyro Mousses, Jeffrey M. Trent, Anthony W. Tolcher, Bodour Salhia, Paul R. Billings, Linh Hoang, Asim Siddiqui, Francisco M. De La Vega, Onur Sakarya, Catalin Barbacioru, Julie Koeman, Angela Baker, Ahmet Kurdoglu, Tyler Izatt, Cynthia R. Osborne, Cristi L. Aitelli, Joanne L. Blum, Alexis Christoforides, Jennifer Dinh, Shukmei Wong, Tracy M. Moses, Shripad Sinari, Jessica Aldrich, Jeffrey A. Kiefer, Joyce A. O'Shaughnessy, and David W. Craig

Abstract

PDF file - 1635K, PET/CT images of mTNBC2 breast lesion before and after treatment on combination MEK and AKT inhibitors

Published

2023

27. Supplementary Table 2 from Genome and Transcriptome Sequencing in Prospective Metastatic Triple-Negative Breast Cancer Uncovers Therapeutic Vulnerabilities

Author

John D. Carpten, Daniel Von Hoff, Spyro Mousses, Jeffrey M. Trent, Anthony W. Tolcher, Bodour Salhia, Paul R. Billings, Linh Hoang, Asim Siddiqui, Francisco M. De La Vega, Onur Sakarya, Catalin Barbacioru, Julie Koeman, Angela Baker, Ahmet Kurdoglu, Tyler Izatt, Cynthia R. Osborne, Cristi L. Aitelli, Joanne L. Blum, Alexis Christoforides, Jennifer Dinh, Shukmei Wong, Tracy M. Moses, Shripad Sinari, Jessica Aldrich, Jeffrey A. Kiefer, Joyce A. O'Shaughnessy, and David W. Craig

Abstract

XLSX file - 48K, Transcriptome sequencing (RNA-seq) run statistics for mTNBC

Published

2023

28. Data from Priorities to Promote Participant Engagement in the Participant Engagement and Cancer Genome Sequencing (PE-CGS) Network

Author

John FP. Bridges, Cheryl Willman, Nikhil Wagle, Roel GW. Verhaak, Jeffrey M. Trent, Jessica C. Tiner, Andrew L. Sussman, Mariana C. Stern, Charité Ricker, Timothy R. Rebbeck, Electra D. Paskett, Shiraz I. Mishra, Qin Ma, Heinz-Josef Lenz, Bethany M. Kwan, Katherine A. Janeway, Ryan C. Fields, Bettina F. Drake, Li Ding, Graham A. Colditz, Elizabeth B. Claus, John D. Carpten, Cindy K. Blair, Melinda Bachini, Norah L. Crossnohere, and Anne LR. Schuster

Abstract

Background:Engaging diverse populations in cancer genomics research is of critical importance and is a fundamental goal of the NCI Participant Engagement and Cancer Genome Sequencing (PE-CGS) Network. Established as part of the Cancer Moonshot, PE-CGS is a consortium of stakeholders including clinicians, scientists, genetic counselors, and representatives of potential study participants and their communities. Participant engagement is an ongoing, bidirectional, and mutually beneficial interaction between study participants and researchers. PE-CGS sought to set priorities in participant engagement for conducting the network's research.Methods:PE-CGS deliberatively engaged its stakeholders in the following four-phase process to set the network's research priorities in participant engagement: (i) a brainstorming exercise to elicit potential priorities; (ii) a 2-day virtual meeting to discuss priorities; (iii) recommendations from the PE-CGS External Advisory Panel to refine priorities; and (iv) a virtual meeting to set priorities.Results:Nearly 150 PE-CGS stakeholders engaged in the process. Five priorities were set: (i) tailor education and communication materials for participants throughout the research process; (ii) identify measures of participant engagement; (iii) identify optimal participant engagement strategies; (iv) understand cancer disparities in the context of cancer genomics research; and (v) personalize the return of genomics findings to participants.Conclusions:PE-CGS is pursuing these priorities to meaningfully engage diverse and underrepresented patients with cancer and posttreatment cancer survivors as participants in cancer genomics research and, subsequently, generate new discoveries.Impact:Data from PE-CGS will be shared with the broader scientific community in a manner consistent with participant informed consent and community agreement.

Published

2023

29. Supplementary Figure 2 from Genome and Transcriptome Sequencing in Prospective Metastatic Triple-Negative Breast Cancer Uncovers Therapeutic Vulnerabilities

Author

John D. Carpten, Daniel Von Hoff, Spyro Mousses, Jeffrey M. Trent, Anthony W. Tolcher, Bodour Salhia, Paul R. Billings, Linh Hoang, Asim Siddiqui, Francisco M. De La Vega, Onur Sakarya, Catalin Barbacioru, Julie Koeman, Angela Baker, Ahmet Kurdoglu, Tyler Izatt, Cynthia R. Osborne, Cristi L. Aitelli, Joanne L. Blum, Alexis Christoforides, Jennifer Dinh, Shukmei Wong, Tracy M. Moses, Shripad Sinari, Jessica Aldrich, Jeffrey A. Kiefer, Joyce A. O'Shaughnessy, and David W. Craig

Abstract

PDF file - 135K, Validation of RB1 39bp homozygous deletion in mTNBC1

Published

2023

30. Data from Identification of Recurrent Activating HER2 Mutations in Primary Canine Pulmonary Adenocarcinoma

Author

William P.D. Hendricks, David P. Carbone, Jeffrey M. Trent, Muhammed Murtaza, Timothy G. Whitsett, Krista La Perle, Michael J. Koenig, Sara L. Sinicropi-Yao, Joseph M. Amann, Winnie S. Liang, Kevin Drenner, Shukmei Wong, Salvatore Facista, Alexandra Nazareno, Tania Contente-Cuomo, Nieves Perdigones, Victoria Zismann, Karthigayini Sivaprakasam, and Gwendolen Lorch

Abstract

Purpose:Naturally occurring primary canine lung cancers share clinicopathologic features with human lung cancers in never-smokers, but the genetic underpinnings of canine lung cancer are unknown. We have charted the genomic landscape of canine lung cancer and performed functional characterization of novel, recurrent HER2 (ERBB2) mutations occurring in canine pulmonary adenocarcinoma (cPAC).Experimental Design:We performed multiplatform genomic sequencing of 88 primary canine lung tumors or cell lines. Additionally, in cPAC cell lines, we performed functional characterization of HER2 signaling and evaluated mutation-dependent HER2 inhibitor drug dose-response.Results:We discovered somatic, coding HER2 point mutations in 38% of cPACs (28/74), but none in adenosquamous (cPASC, 0/11) or squamous cell (cPSCC, 0/3) carcinomas. The majority (93%) of HER2 mutations were hotspot V659E transmembrane domain (TMD) mutations comparable to activating mutations at this same site in human cancer. Other HER2 mutations were located in the extracellular domain and TMD. HER2V659E was detected in the plasma of 33% (2/6) of dogs with localized HER2V659E tumors. HER2V659E cPAC cell lines displayed constitutive phosphorylation of AKT and significantly higher sensitivity to the HER2 inhibitors lapatinib and neratinib relative to HER2-wild-type cell lines (IC50 < 200 nmol/L in HER2V659E vs. IC50 > 2,500 nmol/L in HER2WT).Conclusions:This study creates a foundation for molecular understanding of and drug development for canine lung cancer. These data also establish molecular contexts for comparative studies in dogs and humans of low mutation burden, never-smoker lung cancer, and mutant HER2 function and inhibition.

Published

2023

31. Table S5-6 from Ponatinib Shows Potent Antitumor Activity in Small Cell Carcinoma of the Ovary Hypercalcemic Type (SCCOHT) through Multikinase Inhibition

Author

Jeffrey M. Trent, David G. Huntsman, Bernard E. Weissman, Praveen Nair, Barbara C. Vanderhyden, Ralf Hass, Aleksandar Sekulic, Anthony N. Karnezis, Yemin Wang, Michael B. Major, Emily M. Cousins, Victoria L. Zismann, Salvatore J. Facista, Megan Washington, Winnie S. Liang, Nanyun Tang, Chris Sereduk, Elizabeth A. Raupach, Patrick Pirrotte, Ritin Sharma, Pilar Ramos, Jeffrey Kiefer, Hongwei Yin, Krystal A. Orlando, William P.D. Hendricks, and Jessica D. Lang

Abstract

Supplemental Table 5. SCCOHT-1 ABPP data; Supplemental Table 6. BIN67 ABPP data.

Published

2023

32. Figure S3 from Genomic and Transcriptomic Analysis of Relapsed and Refractory Childhood Solid Tumors Reveals a Diverse Molecular Landscape and Mechanisms of Immune Evasion

Author

Jeffrey M. Trent, Giselle L. Saulnier Sholler, Javed Khan, Rebecca F. Halperin, Jonathan J. Keats, Szabolcs Szelinger, Bryce Turner, Austin Christofferson, Faith Cisneros, Apurva M. Hegde, Daniel Enriquez, Tyler Izatt, Sara Nasser, Alison Roos, Hue V. Reardon, Xinyu Wen, Jun S. Wei, Hsien-Chao Chou, Jeffrey Bond, Karl Dykema, Elizabeth VanSickle, Genevieve Bergendahl, Virginia L. Harrod, Peter E. Zage, Kathleen Neville, Jawhar Rawwas, Randal K. Wada, Javier E. Oesterheld, Michael S. Isakoff, William Roberts, Albert Cornelius, Deanna Mitchell, Don E. Eslin, Valerie I. Brown, William S. Ferguson, Jacqueline M. Kraveka, Abhinav B. Nagulapally, William P.D. Hendricks, and Sara A. Byron

Abstract

Most Variably Expressed Genes in Relapsed and Refractory Childhood Solid Tumors.

Published

2023

33. Data from SDHD Promoter Mutations Ablate GABP Transcription Factor Binding in Melanoma

Author

Kevin M. Brown, Michiel Vermeulen, Nicholas K. Hayward, Jeffrey M. Trent, Esther Willems, Jun Fang, Michael Kovacs, Christine Lee, Matthew M. Makowski, Mai Xu, and Tongwu Zhang

Abstract

SDHD encodes subunit D of the succinate dehydrogenase complex, an integral membrane protein. Across cancer types, recurrent SDHD promoter mutations were reported to occur exclusively in melanomas, at a frequency of 4% to 5%. These mutations are predicted to disrupt consensus ETS transcription factor–binding sites and are correlated with both reduced SDHD gene expression and poor prognosis. However, the consequence of these mutations on SDHD expression in melanoma is still unclear. Here, we found that expression of SDHD in melanoma correlated with the expression of multiple ETS transcription factors, particularly in SDHD promoter wild-type samples. Consistent with the predicted loss of ETS transcription factor binding, we observed that recurrent hotspot mutations resulted in decreased luciferase activity in reporter assays. Furthermore, we demonstrated specific GABPA and GABPB1 binding to probes containing the wild-type promoter sequences, with binding disrupted by the SDHD hotspot promoter mutations in both quantitative mass spectrometry and band-shift experiments. Finally, using siRNA-mediated knockdown across multiple melanoma cell lines, we determined that loss of GABPA resulted in reduced SDHD expression at both RNA and protein levels. These data are consistent with a key role for GABPA/B1 as the critical ETS transcription factors deregulating SDHD expression in the context of highly recurrent promoter mutations in melanoma and warrant a detailed search for other recurrent promoter mutations that create or disrupt GABPA consensus sequences. Cancer Res; 77(7); 1649–61. ©2017 AACR.

Published

2023

34. Figure S6 from Identification of Recurrent Activating HER2 Mutations in Primary Canine Pulmonary Adenocarcinoma

Author

William P.D. Hendricks, David P. Carbone, Jeffrey M. Trent, Muhammed Murtaza, Timothy G. Whitsett, Krista La Perle, Michael J. Koenig, Sara L. Sinicropi-Yao, Joseph M. Amann, Winnie S. Liang, Kevin Drenner, Shukmei Wong, Salvatore Facista, Alexandra Nazareno, Tania Contente-Cuomo, Nieves Perdigones, Victoria Zismann, Karthigayini Sivaprakasam, and Gwendolen Lorch

Abstract

HER2 cellular location and function in primary canine lung cancer. (A) Canine papillary adenocarcinoma with intense, complete, circumferential membrane (white arrow) and lateral cytoplasmic membrane (black arrow) anti-HER2 antibody positive staining (brown) in a patient with wild-type HER2. (B) Canine papillary adenocarcinoma with moderate cytoplasmic (black arrow) anti-HER2 antibody positive staining (light brown) in a patient with wild-type HER2. x 40; bar 50 µm. (C) Anti-HER2 immunohistochemistry of a Grade 1 canine papillary adenocarcinoma wild type for HER2. x 20. (D) Segmentation mark-up of the tumor from adjacent normal lung. Tumor is identified by green, whereas red is area within tumor that contains no tissue, and yellow represents areas of non-tumor such as necrosis or tumor stroma. x20.

Published

2023

35. Figure S6 from Arginine Depletion Therapy with ADI-PEG20 Limits Tumor Growth in Argininosuccinate Synthase–Deficient Ovarian Cancer, Including Small-Cell Carcinoma of the Ovary, Hypercalcemic Type

Author

David G. Huntsman, Yemin Wang, Patrick Pirrotte, Lynn Hoang, Jeffrey M. Trent, Bernard E. Weissman, C. Blake Gilks, Jessica N. McAlpine, Gregg B. Morin, Anthony Karnezis, Friedrich Kommoss, Gian Luca Negri, Shane Colborne, Christine Chow, Angela Cheng, Samuel Leung, David Farnell, Isabel N. Alcazar, Khyatiben V. Pathak, Germain Ho, Shary Yutin Chen, Basile Tessier-Cloutier, Dawn R. Cochrane, and Jennifer X. Ji

Abstract

IC50 curves for ADI-PEG20 in ovarian cancer cell lines. A, ASS1-deficient ovarian cancer cell lines and B, ASS1-proficient ovarian cancer cell lines.

Published

2023

36. Supplementary Figures and Tables from SDHD Promoter Mutations Ablate GABP Transcription Factor Binding in Melanoma

Author

Kevin M. Brown, Michiel Vermeulen, Nicholas K. Hayward, Jeffrey M. Trent, Esther Willems, Jun Fang, Michael Kovacs, Christine Lee, Matthew M. Makowski, Mai Xu, and Tongwu Zhang

Abstract

Supplementary Figure 1. Confirmation of the recurrent C524, C541 and C544 SDHD promoter mutations in melanoma cell lines via Sanger sequencing. Supplementary Figure 2. Expression of SDHD in melanomas harboring promoter mutations compared to SDHD wild-type samples across TCGA samples. Supplementary Figure 3. Luciferase reporter assays for the C541T and C544T SDHD hotspot promoter mutations in multiple melanoma cell lines. Supplementary Figure 4. Prediction of the consequences of the C541T and C544T SDHD promoter mutations on transcription factor binding. Supplementary Figure 5. mRNA expression correlation between SDHD and multiple ETS transcription factors in TCGA SKCM samples harboring the SDHD C523T promoter mutation. Supplementary Figure 6. Band-shift analysis of recombinant human ELF1 binding to wild-type and C523T, C524T, C541T, and C544T SDHD promoter sequences. Supplementary Figure 7. Effect of siRNA-mediated knockdown of ELF1 on SDHD expression in melanoma cells. Supplementary Figure 8. Effect of siRNA-mediated knockdown of PRDM1 or IRF4 on SDHD expression and SDHD promoter activity in melanoma cells. Supplementary Table 1. SDHD promoter mutations identified in melanoma tumors datasets (TCGA, Broad and Yale) and melanoma cell lines. Supplementary Table 2. MotifBreakR results predicting the effects of recurrent SDHD promoter mutations (C523T, C524T, C541T, C544T, and C548T) on transcription factor binding sites. Supplementary Table 3. Oligonucleotide design for quantitative mass spectrometry.

Published

2023

37. Table S3 from Ponatinib Shows Potent Antitumor Activity in Small Cell Carcinoma of the Ovary Hypercalcemic Type (SCCOHT) through Multikinase Inhibition

Author

Jeffrey M. Trent, David G. Huntsman, Bernard E. Weissman, Praveen Nair, Barbara C. Vanderhyden, Ralf Hass, Aleksandar Sekulic, Anthony N. Karnezis, Yemin Wang, Michael B. Major, Emily M. Cousins, Victoria L. Zismann, Salvatore J. Facista, Megan Washington, Winnie S. Liang, Nanyun Tang, Chris Sereduk, Elizabeth A. Raupach, Patrick Pirrotte, Ritin Sharma, Pilar Ramos, Jeffrey Kiefer, Hongwei Yin, Krystal A. Orlando, William P.D. Hendricks, and Jessica D. Lang

Abstract

IC50 summary of validated drug hits in SCCOHT cell lines.

Published

2023

38. Figure S1 from Prospective Feasibility Trial for Genomics-Informed Treatment in Recurrent and Progressive Glioblastoma

Author

Michael D. Prados, David W. Craig, John D. Carpten, Michael E. Berens, Jeffrey M. Trent, Winnie S. Liang, Sara Nasser, Sen Peng, Gerald M. Maggiora, Annette M. Molinaro, Mitchel S. Berger, Susan M. Chang, Jennifer L. Clarke, Jennie W. Taylor, Nicholas A. Butowski, Ingo K. Mellinghoff, Timothy F. Cloughesy, Patrick Y. Wen, Keith L. Ligon, Howard Colman, John F. de Groot, John G. Kuhn, Joanna J. Phillips, Rebecca F. Halperin, Nhan L. Tran, and Sara A. Byron

Abstract

Study Workflow Diagram. Key steps in the study are outlined, including the number of patients at each stage. BEV: bevacizumab.

Published

2023

39. Supplementary Figures and Methods from HACE1 Prevents Lung Carcinogenesis via Inhibition of RAC-Family GTPases

Author

Josef M. Penninger, Poul H. Sorensen, Astrid Hagelkruys, Mads Daugaard, Fumiyo Ikeda, Jeffrey M. Trent, David A. Williams, Maria Novatchkova, Domagoj Cikes, David Hoffmann, Iris Uribesalgo, Shuan Rao, Bianca V. Gapp, Anoop M. Kavirayani, Davide Tortora, Roberto Nitsch, Carlos Gomez-Diaz, Stefan Mereiter, Amal M. El-Naggar, Alexandra Leopoldi, Gian Luca Negri, Luigi Tortola, and Melanie Kogler

Abstract

Supplementary Figures (Fig.S1-S4) and Supplementary Materials and Methods. Supplementary Figure S1. Loss of Hace1 results in increased lung tumorigenesis independent of RIPK3. Supplementary Figure S2. Analysis of RAC, NRF2 and 4HNE expression. Supplementary Figure S3. Analysis of tumor microenvironment. Supplementary Figure S4. Treatment of KRasG12D;Hace1-/- mice with a ROS scavenger diminishes lung tumorigenesis and Hace1-deficient cells are sensitive to exogenous induction of oxidative stress.

Published

2023

40. Supplemental Tables S1-S12 from Genomic and Transcriptomic Analysis of Relapsed and Refractory Childhood Solid Tumors Reveals a Diverse Molecular Landscape and Mechanisms of Immune Evasion

Author

Jeffrey M. Trent, Giselle L. Saulnier Sholler, Javed Khan, Rebecca F. Halperin, Jonathan J. Keats, Szabolcs Szelinger, Bryce Turner, Austin Christofferson, Faith Cisneros, Apurva M. Hegde, Daniel Enriquez, Tyler Izatt, Sara Nasser, Alison Roos, Hue V. Reardon, Xinyu Wen, Jun S. Wei, Hsien-Chao Chou, Jeffrey Bond, Karl Dykema, Elizabeth VanSickle, Genevieve Bergendahl, Virginia L. Harrod, Peter E. Zage, Kathleen Neville, Jawhar Rawwas, Randal K. Wada, Javier E. Oesterheld, Michael S. Isakoff, William Roberts, Albert Cornelius, Deanna Mitchell, Don E. Eslin, Valerie I. Brown, William S. Ferguson, Jacqueline M. Kraveka, Abhinav B. Nagulapally, William P.D. Hendricks, and Sara A. Byron

Abstract

Table S1. Extended Cohort Annotations. Table S2. Mutational Signatures. Table S3. GISTIC Copy Number Analysis. Table S4. Somatic Variants in Relapsed/Refractory Childhood Solid Tumors (n=184 Patients with T/N WES). Table S5. Clinvar Pathogenic and Likely Pathogenic Germline Variants in Relapsed/Refractory Childhood Solid Tumors(n=184 Patients with T/N WES). Table S6. Gene Lists. Table S7. Log2(TPM+1) Values for the 2,199 Most Variable Genes Expressed Across the Cohort of Relapsed/Refractory Childhood Solid Tumors with RNA-seq (n=245). Table S8. Differential Expression Analysis of 2,199 Most Variable Genes Among Clusters. Table S9. Genes Filtered for COSMIC, Transcription Factors and Potential Drug Targets from Table S8 with log2FC greater than or equal to 2. Table S10. Differential Expression Analysis Among C3a, C3b, and C3c Subclusters. Table S11. Samples Falling in Clusters C3a-C3c and Genes that are Uniformly Highly Expressed in the Clusters. Table S12. Longitudinal Samples.

Published

2023

41. Data from HACE1 Prevents Lung Carcinogenesis via Inhibition of RAC-Family GTPases

Author

Josef M. Penninger, Poul H. Sorensen, Astrid Hagelkruys, Mads Daugaard, Fumiyo Ikeda, Jeffrey M. Trent, David A. Williams, Maria Novatchkova, Domagoj Cikes, David Hoffmann, Iris Uribesalgo, Shuan Rao, Bianca V. Gapp, Anoop M. Kavirayani, Davide Tortora, Roberto Nitsch, Carlos Gomez-Diaz, Stefan Mereiter, Amal M. El-Naggar, Alexandra Leopoldi, Gian Luca Negri, Luigi Tortola, and Melanie Kogler

Abstract

HACE1 is an E3 ubiquitin ligase with important roles in tumor biology and tissue homeostasis. Loss or mutation of HACE1 has been associated with the occurrence of a variety of neoplasms, but the underlying mechanisms have not been defined yet. Here, we report that HACE1 is frequently mutated in human lung cancer. In mice, loss of Hace1 led to enhanced progression of KRasG12D-driven lung tumors. Additional ablation of the oncogenic GTPase Rac1 partially reduced progression of Hace1−/− lung tumors. RAC2, a novel ubiquitylation target of HACE1, could compensate for the absence of its homolog RAC1 in Hace1-deficient, but not in HACE1-sufficient tumors. Accordingly, ablation of both Rac1 and Rac2 fully averted the increased progression of KRasG12D-driven lung tumors in Hace1−/− mice. In patients with lung cancer, increased expression of HACE1 correlated with reduced levels of RAC1 and RAC2 and prolonged survival, whereas elevated expression of RAC1 and RAC2 was associated with poor prognosis. This work defines HACE1 as a crucial regulator of the oncogenic activity of RAC-family GTPases in lung cancer development.Significance:These findings reveal that mutation of the tumor suppressor HACE1 disrupts its role as a regulator of the oncogenic activity of RAC-family GTPases in human and murine lung cancer.

Published

2023

42. Supplemental Table S1 from Arginine Depletion Therapy with ADI-PEG20 Limits Tumor Growth in Argininosuccinate Synthase–Deficient Ovarian Cancer, Including Small-Cell Carcinoma of the Ovary, Hypercalcemic Type

Author

David G. Huntsman, Yemin Wang, Patrick Pirrotte, Lynn Hoang, Jeffrey M. Trent, Bernard E. Weissman, C. Blake Gilks, Jessica N. McAlpine, Gregg B. Morin, Anthony Karnezis, Friedrich Kommoss, Gian Luca Negri, Shane Colborne, Christine Chow, Angela Cheng, Samuel Leung, David Farnell, Isabel N. Alcazar, Khyatiben V. Pathak, Germain Ho, Shary Yutin Chen, Basile Tessier-Cloutier, Dawn R. Cochrane, and Jennifer X. Ji

Abstract

Table containing proteins differentially expressed in at least two rarer ovarian cancer subtypes when compared to HGSC.

Published

2023

43. Supplementary Legend from Identification of Recurrent Activating HER2 Mutations in Primary Canine Pulmonary Adenocarcinoma

Author

William P.D. Hendricks, David P. Carbone, Jeffrey M. Trent, Muhammed Murtaza, Timothy G. Whitsett, Krista La Perle, Michael J. Koenig, Sara L. Sinicropi-Yao, Joseph M. Amann, Winnie S. Liang, Kevin Drenner, Shukmei Wong, Salvatore Facista, Alexandra Nazareno, Tania Contente-Cuomo, Nieves Perdigones, Victoria Zismann, Karthigayini Sivaprakasam, and Gwendolen Lorch

Abstract

Supplementary Legend

Published

2023

44. Data from Ponatinib Shows Potent Antitumor Activity in Small Cell Carcinoma of the Ovary Hypercalcemic Type (SCCOHT) through Multikinase Inhibition

Author

Jeffrey M. Trent, David G. Huntsman, Bernard E. Weissman, Praveen Nair, Barbara C. Vanderhyden, Ralf Hass, Aleksandar Sekulic, Anthony N. Karnezis, Yemin Wang, Michael B. Major, Emily M. Cousins, Victoria L. Zismann, Salvatore J. Facista, Megan Washington, Winnie S. Liang, Nanyun Tang, Chris Sereduk, Elizabeth A. Raupach, Patrick Pirrotte, Ritin Sharma, Pilar Ramos, Jeffrey Kiefer, Hongwei Yin, Krystal A. Orlando, William P.D. Hendricks, and Jessica D. Lang

Abstract

Purpose: Small cell carcinoma of the ovary, hypercalcemic type (SCCOHT) is a rare, aggressive ovarian cancer in young women that is universally driven by loss of the SWI/SNF ATPase subunits SMARCA4 and SMARCA2. A great need exists for effective targeted therapies for SCCOHT.Experimental Design: To identify underlying therapeutic vulnerabilities in SCCOHT, we conducted high-throughput siRNA and drug screens. Complementary proteomics approaches profiled kinases inhibited by ponatinib. Ponatinib was tested for efficacy in two patient-derived xenograft (PDX) models and one cell-line xenograft model of SCCOHT.Results: The receptor tyrosine kinase (RTK) family was enriched in siRNA screen hits, with FGFRs and PDGFRs being overlapping hits between drug and siRNA screens. Of multiple potent drug classes in SCCOHT cell lines, RTK inhibitors were only one of two classes with selectivity in SCCOHT relative to three SWI/SNF wild-type ovarian cancer cell lines. We further identified ponatinib as the most effective clinically approved RTK inhibitor. Reexpression of SMARCA4 was shown to confer a 1.7-fold increase in resistance to ponatinib. Subsequent proteomic assessment of ponatinib target modulation in SCCOHT cell models confirmed inhibition of nine known ponatinib target kinases alongside 77 noncanonical ponatinib targets in SCCOHT. Finally, ponatinib delayed tumor doubling time 4-fold in SCCOHT-1 xenografts while reducing final tumor volumes in SCCOHT PDX models by 58.6% and 42.5%.Conclusions: Ponatinib is an effective agent for SMARCA4-mutant SCCOHT in both in vitro and in vivo preclinical models through its inhibition of multiple kinases. Clinical investigation of this FDA-approved oncology drug in SCCOHT is warranted. Clin Cancer Res; 24(8); 1932–43. ©2018 AACR.

Published

2023

45. Data from Arginine Depletion Therapy with ADI-PEG20 Limits Tumor Growth in Argininosuccinate Synthase–Deficient Ovarian Cancer, Including Small-Cell Carcinoma of the Ovary, Hypercalcemic Type

Author

David G. Huntsman, Yemin Wang, Patrick Pirrotte, Lynn Hoang, Jeffrey M. Trent, Bernard E. Weissman, C. Blake Gilks, Jessica N. McAlpine, Gregg B. Morin, Anthony Karnezis, Friedrich Kommoss, Gian Luca Negri, Shane Colborne, Christine Chow, Angela Cheng, Samuel Leung, David Farnell, Isabel N. Alcazar, Khyatiben V. Pathak, Germain Ho, Shary Yutin Chen, Basile Tessier-Cloutier, Dawn R. Cochrane, and Jennifer X. Ji

Abstract

Purpose:Many rare ovarian cancer subtypes, such as small-cell carcinoma of the ovary, hypercalcemic type (SCCOHT), have poor prognosis due to their aggressive nature and resistance to standard platinum- and taxane-based chemotherapy. The development of effective therapeutics has been hindered by the rarity of such tumors. We sought to identify targetable vulnerabilities in rare ovarian cancer subtypes.Experimental Design:We compared the global proteomic landscape of six cases each of endometrioid ovarian cancer (ENOC), clear cell ovarian cancer (CCOC), and SCCOHT to the most common subtype, high-grade serous ovarian cancer (HGSC), to identify potential therapeutic targets. IHC of tissue microarrays was used as validation of arginosuccinate synthase (ASS1) deficiency. The efficacy of arginine-depriving therapeutic ADI-PEG20 was assessed in vitro using cell lines and patient-derived xenograft mouse models representing SCCOHT.Results:Global proteomic analysis identified low ASS1 expression in ENOC, CCOC, and SCCOHT compared with HGSC. Low ASS1 levels were validated through IHC in large patient cohorts. The lowest levels of ASS1 were observed in SCCOHT, where ASS1 was absent in 12 of 31 cases, and expressed in less than 5% of the tumor cells in 9 of 31 cases. ASS1-deficient ovarian cancer cells were sensitive to ADI-PEG20 treatment regardless of subtype in vitro. Furthermore, in two cell line mouse xenograft models and one patient-derived mouse xenograft model of SCCOHT, once-a-week treatment with ADI-PEG20 (30 mg/kg and 15 mg/kg) inhibited tumor growth in vivo.Conclusions:Preclinical in vitro and in vivo studies identified ADI-PEG20 as a potential therapy for patients with rare ovarian cancers, including SCCOHT.

Published

2023

46. Figures S1-3 from Ponatinib Shows Potent Antitumor Activity in Small Cell Carcinoma of the Ovary Hypercalcemic Type (SCCOHT) through Multikinase Inhibition

Author

Jeffrey M. Trent, David G. Huntsman, Bernard E. Weissman, Praveen Nair, Barbara C. Vanderhyden, Ralf Hass, Aleksandar Sekulic, Anthony N. Karnezis, Yemin Wang, Michael B. Major, Emily M. Cousins, Victoria L. Zismann, Salvatore J. Facista, Megan Washington, Winnie S. Liang, Nanyun Tang, Chris Sereduk, Elizabeth A. Raupach, Patrick Pirrotte, Ritin Sharma, Pilar Ramos, Jeffrey Kiefer, Hongwei Yin, Krystal A. Orlando, William P.D. Hendricks, and Jessica D. Lang

Abstract

Supplemental Figure 1. COV434-pIND20-Brg1 SMARCA4 induction optimization; Supplemental Figure 2. Kinase hits from siRNA screen mapped to kinome dendrogram; Supplemental Figure 3. ClueGo analysis of validated siRNA screen hits.

Published

2023

47. Tables S1 to S13 from Identification of Recurrent Activating HER2 Mutations in Primary Canine Pulmonary Adenocarcinoma

Author

William P.D. Hendricks, David P. Carbone, Jeffrey M. Trent, Muhammed Murtaza, Timothy G. Whitsett, Krista La Perle, Michael J. Koenig, Sara L. Sinicropi-Yao, Joseph M. Amann, Winnie S. Liang, Kevin Drenner, Shukmei Wong, Salvatore Facista, Alexandra Nazareno, Tania Contente-Cuomo, Nieves Perdigones, Victoria Zismann, Karthigayini Sivaprakasam, and Gwendolen Lorch

Abstract

Supplementary Table 1. Informatic tools utilized in primary canine lung cancer analysis Supplementary Table 2. Extended clinical and multiplatform annotation of primary canine lung cancer cases. Supplementary Table 3 : Sequencing metrics for primary canine lung cancer exome analysis. Supplementary Table 4. Somatic coding SNVs identified by exome sequencing of primary canine lung cancers. Supplementary Table 5. Somatic copy number variants identified by exome sequencing in primary canine lung cancers. Supplementary Table 6. Somatic coding structural variants identified by exome sequencing of primary canine lung cancers. Supplementary Table 7. Canine genomic regions covered by custom amplicon panel. Supplementary Table 8. Sequencing metrics for primary canine lung cancer amplicon analysis. Supplementary Table 9. Somatic coding SNVs identified by panel sequencing of primary canine lung cancers. Supplementary Table 10. Germline SNPs in COSMIC Tier 1 cancer genes identified by exome and panel sequencing in primary canine lung cancers. Supplementary Table 11. Multi-platform validation of HER2 mutations. Supplementary Table 12. Non-invasive detection of HER2V659E in the plasma of primary canine lung cancer patients. Supplementary Table 13. HER2 protein expression and quantification by immunohistochemistry.

Published

2023

48. Supplementary Methods from Arginine Depletion Therapy with ADI-PEG20 Limits Tumor Growth in Argininosuccinate Synthase–Deficient Ovarian Cancer, Including Small-Cell Carcinoma of the Ovary, Hypercalcemic Type

Author

David G. Huntsman, Yemin Wang, Patrick Pirrotte, Lynn Hoang, Jeffrey M. Trent, Bernard E. Weissman, C. Blake Gilks, Jessica N. McAlpine, Gregg B. Morin, Anthony Karnezis, Friedrich Kommoss, Gian Luca Negri, Shane Colborne, Christine Chow, Angela Cheng, Samuel Leung, David Farnell, Isabel N. Alcazar, Khyatiben V. Pathak, Germain Ho, Shary Yutin Chen, Basile Tessier-Cloutier, Dawn R. Cochrane, and Jennifer X. Ji

Abstract

Supplemental material and methods

Published

2023

49. Supplementary Table S1 from HACE1 Prevents Lung Carcinogenesis via Inhibition of RAC-Family GTPases

Author

Josef M. Penninger, Poul H. Sorensen, Astrid Hagelkruys, Mads Daugaard, Fumiyo Ikeda, Jeffrey M. Trent, David A. Williams, Maria Novatchkova, Domagoj Cikes, David Hoffmann, Iris Uribesalgo, Shuan Rao, Bianca V. Gapp, Anoop M. Kavirayani, Davide Tortora, Roberto Nitsch, Carlos Gomez-Diaz, Stefan Mereiter, Amal M. El-Naggar, Alexandra Leopoldi, Gian Luca Negri, Luigi Tortola, and Melanie Kogler

Abstract

HACE1 mutational landscape in human cancer.

Published

2023

50. Data from Prospective Feasibility Trial for Genomics-Informed Treatment in Recurrent and Progressive Glioblastoma

Author

Michael D. Prados, David W. Craig, John D. Carpten, Michael E. Berens, Jeffrey M. Trent, Winnie S. Liang, Sara Nasser, Sen Peng, Gerald M. Maggiora, Annette M. Molinaro, Mitchel S. Berger, Susan M. Chang, Jennifer L. Clarke, Jennie W. Taylor, Nicholas A. Butowski, Ingo K. Mellinghoff, Timothy F. Cloughesy, Patrick Y. Wen, Keith L. Ligon, Howard Colman, John F. de Groot, John G. Kuhn, Joanna J. Phillips, Rebecca F. Halperin, Nhan L. Tran, and Sara A. Byron

Abstract

Purpose: Glioblastoma is an aggressive and molecularly heterogeneous cancer with few effective treatment options. We hypothesized that next-generation sequencing can be used to guide treatment recommendations within a clinically acceptable time frame following surgery for patients with recurrent glioblastoma.Experimental Design: We conducted a prospective genomics-informed feasibility trial in adults with recurrent and progressive glioblastoma. Following surgical resection, genome-wide tumor/normal exome sequencing and tumor RNA sequencing were performed to identify molecular targets for potential matched therapy. A multidisciplinary molecular tumor board issued treatment recommendations based on the genomic results, blood–brain barrier penetration of the indicated therapies, drug–drug interactions, and drug safety profiles. Feasibility of generating genomics-informed treatment recommendations within 35 days of surgery was assessed.Results: Of the 20 patients enrolled in the study, 16 patients had sufficient tumor tissue for analysis. Exome sequencing was completed for all patients, and RNA sequencing was completed for 14 patients. Treatment recommendations were provided within the study's feasibility time frame for 15 of 16 (94%) patients. Seven patients received treatment based on the tumor board recommendations. Two patients reached 12-month progression-free survival, both adhering to treatments based on the molecular profiling results. One patient remained on treatment and progression free 21 months after surgery, 3 times longer than the patient's previous time to progression. Analysis of matched nonenhancing tissue from 12 patients revealed overlapping as well as novel putatively actionable genomic alterations.Conclusions: Use of genome-wide molecular profiling is feasible and can be informative for guiding real-time, central nervous system–penetrant, genomics-informed treatment recommendations for patients with recurrent glioblastoma. Clin Cancer Res; 24(2); 295–305. ©2017 AACR.See related commentary by Wick and Kessler, p. 256

Published

2023